1. Clinically Significant Drug Interactions

2. Drug Interaction Definition
A clinically meaningful alteration in the effect of one drug as a result of coadministration of another
Drug affected by interaction is called the “object drug”
Drug causing interaction is called the “precipitant drug”
Interactions may be desirable or undesirable

3. Types of Drug Interactions
Drug-drug
Drug-disease
Drug-herbal
Drug-alcohol
Drug-food
Drug-nutritional status
Drug-lab

4. Mechanisms of Drug Interactions
Pharmacokinetic interactions
Percipitant drug affects the absorption, distribution, metabolism, or excretion of object drug
Pharmacodynamic interactions
Effect of object drug is modified by the precipitant without changes in pharmacokinetics of object drug

5. Pharmacokinetic Drug Interactions
Inhibition of Absorption
Mechanism
Examples
Drug binding in GIT
Iron may chelate ciprofloxacin, resulting in decreased absorption
GI motility
Increased GI motility caused by metoclopramide may decrease cefprozil absorption
GI pH
GI alkalinization by omeprazole may decrease absorption of ketoconazole
GI flora
Decreased GI bacterial flora caused by antibiotic administration could decrease bacterial production of vitamin K, augmenting the anticoagulant effect of warfarin

6. Pharmacokinetic Drug Interactions
Distribution
Mechanism
Examples
Displacement from plasma proteins
Displacement of methotrexate from plasma proteins by NSAIDs may increase risk of methotrexate toxicity

7. Pharmacokinetic Drug Interactions
Metabolism
Enzymes associated with drug metabolism are called cytochrome P450 enzymes
‘’cytochrome’’ is derived from color of liver cells (dark red) attributed to iron content of the enzymes
P450 refers to ultraviolet light wavelength absorbed by enzymes

8. Pharmacokinetic Drug Interactions
Metabolism
Cytochrome P450 nomenclature
CYP3A4
CYP Human cytochrome P450
Family
A Subfamily
Gene
Enzymes belonging to the 3A and 2D subfamilies account for most of the well-identified drug interactions

9. Pharmacokinetic Drug Interactions
Metabolism
Drugs that undergo hepatic biotransformation are frequently substrates for the same enzymes
While requiring these enzymes for their own metabolism, they also may induce or inhibit enzyme activity on other drugs taken concurrently

10. Pharmacokinetic Drug Interactions
Metabolism
Mechanism
Examples
Enzyme Inhibition Resulting in Increasing Risk of Toxicity
Inhibitors of CYP2C9 (e.g. amiodarone) can increase risk of toxicity from phenytoin, warfarin
Enzyme Inhibition Resulting in Reduced Drug Effect
Analgesic and toxic effects of codeine result from its conversion to morphine by CYP2D6.
Thus, CYP2D6 inhibitors can impair therapeutic effect of codeine.

11. Pharmacokinetic Drug Interactions
Metabolism
Mechanism
Examples
Enzyme Induction Resulting in Reduced Drug Effect
Examples of enzyme inducers include barbiturates, carbamazepine, phenytoin, rifampin
Some drugs, e.g. ritonavir, may act as either an enzyme inhibitor or an enzyme inducer, depending on the situation
Enzyme Induction Resulting in Toxic Metabolites
A small amount of acetaminophen is converted to a cytototoxic metabolite
Enzyme inducers can increase formation of toxic metabolite & increase risk of hepatotoxicity
N-acetyl-p-benzoquinone imine (NAPQI)

12. Pharmacokinetic Drug Interactions
Elimination
Altered Renal Elimination
For some drugs, active secretion into the renal tubules is an important route of elimination
Example
Digoxin is eliminated primarily through renal excretion, and drugs such as amiodarone, clarithromycin, itraconazole can inhibit this process. Digoxin toxicity may result.

13. P-Glycoprotein
P-glycoprotein is a transporter found in the liver, intestine, kidney, and brain
P-glycoprotein acts as an efflux pump to pump toxic materials out of the cell
Example
Digoxin, a PGP substrate
Quinidine is a PGP inhibitor. It inhibits expulsion of digoxin back into intestine, so increases digoxin concentrations
Rifampicin stimulates PGP and so decreases serum digoxin

14. P-Glycoprotein
In the kidney there is a similar effect with PGP enhancing clearance of substances
Quinidine and cyclosporine inhibit PGP, so clearance of digoxin is inhibited
In the CNS, PGP inhibits the passage of some medicines across the blood–brain barrier, e.g. loperamide
A PGP inhibitor allows greater passage across the blood– brain barrier

15. Examples of P-glycoprotein Substrates/Inhibitors/Inducers
Amitriptyline
Atorvastatin
Azithromycin
Carvedilol
Colchicine
Cyclosporine Dexamethasone
Digoxin
Erythromycin
Ethinyl estradiol
Glyburide
Amiodarone
Clarithromycin
Cyclosporine
Diltiazem
Felodipine
Indinavir
Itraconazole
Ketoconazole
Nicardipine
Quinidine
Ritonavir
Sirolimus
Tacrolimus
Verapamil
Rifampin
Carbamazepine
St. John’s wort

16. Pharmacodynamic Drug Interactions
Additive Pharmacodynamic Effects
When two or more drugs with similar pharmacodynamic effects are given, additive effects may result in excessive response and toxicity
Examples
Combining ACEI with potassium-sparing diuretics results in augmented hyperkalemia
Combining a diuretic with a beta blocker provides a greater reduction in blood pressure than either can impart alone

17. Pharmacodynamic Drug Interactions
Antagonistic Pharmacodynamic Effects
Drugs with opposing pharmacodynamic effects may reduce the response to one or both drugs
Example
NSAIDs may inhibit the antihypertensive effect of ACEI
Reduction in the synthesis of the vasodilating renal prostaglandins

18. Drug Interaction Risk Factors
Patient Factors
Number of medications (polypharmacy)
Severity of the diseases being treated
Age (the very young and elderly)
Renal and hepatic dysfunction
Acute medical condition (eg, dehydration, infection)
Pharmacogenetics

19. Drug Interaction Risk Factors
Drug Factors
Higher dose
Narrow therapeutic range (e.g.digoxin)
NSAIDs
Anticoagulants
Hypoglycemics
Antiarrythmics
Anticonvulsants
Antibiotics
Antiretrovirals

20. Drug Interaction Risk Factors
Other Considerations
Increasing use of prescription drugs
Increasing complexity of medication regimens
Fragmented health care system
Incomplete problem or med lists
Multiple prescribers managing
Multiple pharmacies dispensing
Self-medication with OTC, herbals

21. Relevance of Drug Interactions
Impossible to memorize all drug interactions (2500 drug pairs)
Most potential drug interactions never lead to actual clinical effect
Necessary to determine which drug interactions are most clinically important
Ones most likely to cause harm if not detected

22. Drug Interaction Resources
Print & Electronic Resources
Micromedex
Lexicomp
Facts and Comparisons
Hansten and Horn’s The Top 100 Drug Interactions
Stockley's Drug Interactions
Websites
Drug Interaction Checker (Medscape)
Drug Interaction Checker (Drugs.com)

23. Managing Drug Interactions
Comprehensive medication review
Identify potential drug interactions
Assess clinical significance
Continue/discontinue/substitute
Monitor and follow-up
Document
Communicate with patient & healthcare professionals

24. Managing Drug Interactions Tips for Pharmacists
Learn to recognize factors that alter a patient’s risk for an adverse event when exposed to interacting drug pairs
Consider the risk of the potential interaction against the benefit of administering the drugs
If the risk to patient appears to be greater than expected benefit, identify a suitable alternative

25. Managing Drug Interactions Tips for Pharmacists
Drug interaction classification systems should be used for general guidance
No book, PDA, or computer based classification system can replace pharmacist’s informed evaluation
Regard each interaction– patient pair as unique

26. Case Study-1
A 23 y/o woman with a seizure disorder & diabetes is being admitted with ataxia and tremors. She was initiated on Bactrim 10 days ago for UTI. Her Phenytoin level is 28. Her current medication list includes:
Sulfamethoxazole/trimethoprim DS 1 tab po BID
Phenytoin 400 mg po QD
Lantus 15 units SQ q HS
Novolog 5 units SQ with each meal
What actual drug-drug interaction(s) do you identify?
Could it have been prevented? What will you recommend?

27. Case Study-2
A 75 y/o woman with hypertension and atrial fibrillation is prescribed levofloxacin for community acquired pneumonia. Her other medications include:
Sotalol 80 mg PO BID
Aspirin 81 mg PO QD
Enalapril 20 mg PO BID
HCTZ 50 mg PO QD
Felodipine 5mg PO QD
What potential drug-drug interaction(s) do you identify?
What will you recommend?